Plasma display module

ABSTRACT

A plasma display module having an improved grounding structure suitable for manufacturing a lightweight and slim plasma display module. The plasma display module includes: a chassis base formed of a plastic material; a plasma display panel disposed in front of the chassis base to display images; a plurality of circuit substrates disposed on a rear surface of the chassis base to drive the plasma display panel; a grounding member which is disposed corresponding to the circuit substrates so that the chassis base is disposed between the grounding member and the circuit substrates and is formed of a conductive material so that the grounding member can provide a ground voltage to the circuit substrates grounded to the grounding member; and a screw member that electrically connects the circuit substrates to the grounding member through the chassis base and fixes the circuit substrates to the chassis base.

CLAIM OF PRIORITY

This application makes reference to, incorporates the same herein, andclaims all benefits accruing under 35 U.S.C. §119 from an applicationfor PLASMA DISPLAY MODULE earlier filed in the Korean IntellectualProperty Office on 6 Dec. 2005 and there duly assigned Serial No.10-2005-00117843.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a plasma display module, and moreparticularly, to a plasma display module having an improved circuitsubstrate grounding structure suitable to be used to manufacture a slimand light weighted display module.

2. Description of the Related Art

Plasma display modules are flat panel display modules that displayimages by using a discharge effect. Due to their very goodcharacteristics, such as high display capacity, high brightness, highcontrast, high performance, clear latent images, wide viewing angles,slim structure, and large screen size, plasma display devices areconsidered to be the next generation display devices which will replacecathode ray tubes (CRTs).

A plasma display module includes a plasma display panel forming a frontportion of the plasma display module to display images and a chassisbase that supports the plasma display panel from a rear side of theplasma display panel. Circuit substrates that generate predetermineddriving signals to be applied to the plasma display panel are mounted ona rear surface of the chassis base. The driving signals generated by thecircuit substrates are transmitted to the plasma display panel throughconnection cables.

A heat dissipation sheet for transmitting heat generated by theoperation of the plasma display panel to the chassis base may beinterposed between the plasma display panel and the chassis base. Astrip of double-sided tape that intermediates the coupling of the plasmadisplay panel with the chassis base may be interposed between the plasmadisplay panel and the chassis base in areas where the heat dissipationsheet is not interposed. The chassis base serves as a heat dissipationplate that dissipates heat transferred from the plasma display panel tothe outside through by natural convection of air over an outer surfaceof the chassis base. At the same time the chassis base functions as asupporter that supports the plasma display panel disposed in front ofthe chassis base and the circuit substrates disposed on a rear surfaceof the chassis base. Therefore, the chassis base should have amechanical strength greater than a predetermined level to safely protectthe plasma display panel and the circuit substrates from an unexpectedexternal impact. Meanwhile, the chassis base, formed of an electricallyconductive material, has a wide area to provide a grounding region thatmaintains a constant ground voltage, and the circuit substrates mountedon the rear surface of the chassis base have a grounding structure thatmay be directly electrically connected to the chassis base through screwmembers coupled to the chassis base.

To manufacture the chassis base, a method of die-casting or pressing analuminum material to a predetermined shape may be used. Accordingly, thecost of raw materials required may be high, thereby increasingmanufacturing costs. Also, the chassis base formed of an aluminummaterial may be susceptible to bending or twisting due to its materialcharacteristics. Therefore, when an external impact is applied to theplasma display module during transportation or moving, the plasmadisplay panel and the circuit substrates cannot be protected by thechassis base, and therefore, may be damaged by the external impact. Inparticular, as the size of the plasma display panel increases, the sizeof the chassis base, which is proportional to the size of the plasmadisplay panel, also increases, and therefore, becomes more susceptibleto bending or twisting. Therefore, an additional reinforcing structureor reinforcing member for protecting the plasma display panel may berequired.

Also, in that situation, the thickness of the chassis base, generallyformed of aluminum, must be increased to ensure a predeterminedstrength. However, the increased thickness is undesirable for making aslim display module. Furthermore, the chassis base, formed of analuminum material having a specific gravity of approximately 2.7,increases the total weight of the display module. Overall, the chassisbase, formed of an aluminum material, may be a limiting factor in makinga lightweight and slim plasma display module.

Recently, plastic materials are drawing attention as a new material forforming the chassis base since plastic materials having high strengthare advantageous for making lightweight yet strong and slim displaymodules. However, when an insulating plastic material is used formanufacturing the chassis base, the circuit substrates cannot begrounded by conventional grounding method. Therefore, a new groundingstructure for grounding the circuit substrates is required.

SUMMARY OF THE INVENTION

The present invention provides a plasma display module having a circuitsubstrate grounding structure suitable for manufacturing a lightweighted and slim plasma display module.

According to an aspect of the present invention, there is provided aplasma display module comprising a chassis base formed of a non-metallicmaterial; a plasma display panel disposed in front of the chassis baseto display images; a plurality of circuit substrates disposed on a rearsurface of the chassis base to drive the plasma display panel; agrounding member disposed between the chassis base and the plasmadisplay panel, the grounding member being formed of a conductivematerial so that the grounding member can provide a ground voltage tothe circuit substrates when the circuit substrates are grounded to thegrounding member; and a plurality of screw members fixing the circuitsubstrates to the chassis base, at least one of the screw membersgrounding circuit substrates to the grounding member by electricallyconnecting the circuit substrates to the grounding member through thechassis base.

According to the present invention the plasma display module furthercomprises a flexible connection member having a buffering capabilitytogether with electrical conductivity, the flexible connection memberbeing interposed between the chassis base and the grounding member, theflexible connection member forming an electrical connection between theat least one screw member and the grounding member, wherein the at leastone screw member protrudes a predetermined distance from the chassisbase so that the screw member can elastically press the flexibleconnection member against the grounding member, and the flexibleconnection member is formed of a sponge and a metal mesh that surroundsthe sponge.

Additionally, the plasma display module further comprises a flexiblethermal conductive member having a buffering capability together withthermal conductivity, the flexible thermal conductive member beingtightly sandwiched between the chassis base and the grounding member sothat the flexible thermal conductive member can intermediate heattransfer from the chassis base to the grounding member, wherein theflexible thermal conductive member is formed of silicon sheet.

Preferably, the grounding member has a high degree of thermalconductivity for rapidly diffusing heat generated from the plasmadisplay panel, and is made of a metal plate such as aluminum having athermal conductivity of 140 W/mk.

Preferably the chassis base comprises: a plurality of recesses formed ina rear surface area of the chassis base for receiving the plurality ofcircuit substrates; and a plurality of coupling bosses for receiving theplurality of screw members, the coupling bosses being formed as anintegral part of the chassis base protruding from the recesses. Inaddition, the chassis base comprises a plurality of ribs framing theplurality of recesses, the ribs providing added strength and rigidity tothe chassis base. Further, the non-metallic material forming the chassisbase is preferably comprised of a plastic material, a thermoplasticresin material or a thermosetting resin material.

According to another aspect of the present invention, there is provideda plasma display module comprising: a plasma display panel; a chassisbase formed of a non-metallic material, the chassis base being fastenedto the plasma display panel by double sided tape disposed adjacent outeredges of the plasma display panel; a plurality of circuit substratesdisposed on a rear surface of the chassis base to drive the plasmadisplay panel; a grounding member disposed between the plasma displaypanel and the chassis base, the grounding member being formed of aconductive material; and a plurality of screw members fixing theplurality of circuit substrates to the chassis base, at least one of thescrew members grounding the circuit substrates to the grounding memberby electrically connecting the circuit substrates to the groundingmember through the chassis base, wherein the non-metallic materialforming the chassis base is comprised of a plastic material, athermoplastic resin material or a thermosetting resin material.

Additionally, the chassis base comprises: a plurality of recesses formedin a rear surface area of the chassis base for receiving the pluralityof circuit substrates; a plurality of coupling bosses for receiving theplurality of screw members, the coupling bosses being formed as anintegral part of the chassis base protruding from the recesses, and aplurality of ribs framing the plurality of recesses, the ribs providingadded strength and rigidity to the chassis base.

Further, the plasma display module comprises: flexible connectionmembers having a buffering capability together with electricalconductivity, the flexible connection members being tightly sandwichedbetween the chassis base and the grounding member, at least one of theflexible connection members forming an electrical connection between theat least one screw member and the grounding member; and a flexiblethermal conductive member disposed between the flexible connectionmembers, the flexible thermal conductive member having a bufferingcapability together with thermal conductivity, the flexible thermalconductive member being tightly sandwiched between the chassis base andthe grounding member so that the flexible thermal conductive member canintermediate heat transfer from the chassis base to the groundingmember.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete appreciation of the invention, and many of the attendantadvantages thereof, will be readily apparent as the same becomes betterunderstood by reference to the following detailed description whenconsidered in conjunction with the accompanying drawings in which likereference symbols indicate the same or similar components, wherein:

FIG. 1 is a partial perspective view of an example of a plasma displaymodule;

FIG. 2 is an exploded perspective view of a plasma display module,according to an embodiment of the present invention;

FIG. 3 is a perspective view of a chassis base of FIG. 2, according toan embodiment of the present invention;

FIG. 4 is a perspective view of a flexible connection material of FIG.2, according to an embodiment of the present invention; and

FIG. 5 is a cross-sectional view of the plasma display module takenalong line V-V of FIG. 2, according to an embodiment of the presentinvention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention will now be described more fully with reference tothe accompanying drawings in which exemplary embodiments of theinvention are shown.

FIG. 1 is a perspective view of an example of plasma display module. Theplasma display module includes a plasma display panel 30 forming a frontportion of the plasma display module to display images and a chassisbase 60 that supports the plasma display panel 30 from a rear side ofthe plasma display panel 30. Circuit substrates 71 that generatepredetermined driving signals to be applied to the plasma display panel30 are mounted on a rear surface of the chassis base 60. The drivingsignals generated by the circuit substrates 71 are transmitted to theplasma display panel 30 through connection cables 73.

A heat dissipation sheet 40 for transmitting heat generated by theoperation of the plasma display panel 30 to the chassis base 60 isinterposed between the plasma display panel 30 and the chassis base 60.A strip of double-sided tape 50 that intermediates the coupling of theplasma display panel 30 with the chassis base 60 is interposed betweenthe plasma display panel 30 and the chassis base 60 in areas where theheat dissipation sheet 40 is not interposed. The chassis base 60 servesas a heat dissipation plate that dissipates heat transferred from theplasma display panel 30 to the outside through by natural convection ofair over an outer surface of the chassis base 60. At the same time thechassis base 60 functions as a supporter that supports the plasmadisplay panel 30 disposed in front of the chassis base 60 and thecircuit substrates 71 disposed on a rear surface of the chassis base 60.Therefore, the chassis base 60 is required to have a mechanical strengthgreater than a predetermined level to safely protect the plasma displaypanel 30 and the circuit substrates 71 from an unexpected externalimpact. Meanwhile, the chassis base 60, formed of an electricallyconductive material, has a wide area to provide a grounding region thatmaintains a constant ground voltage, and the circuit substrates 71mounted on the rear surface of the chassis base 60 have a groundingstructure that is directly electrically connected to the chassis base 60through screw members 80 coupled to the chassis base 60.

To manufacture the chassis base 60, a method of die-casting or pressingan aluminum material to a predetermined shape is used. Accordinglymethod, the cost of raw materials required is high, thereby increasingmanufacturing costs. Also, the chassis base 60 formed of an aluminummaterial is susceptible to bending or twisting due to its materialcharacteristics. Therefore, when an external impact is applied to theplasma display module during transportation or moving, the plasmadisplay panel 30 and the circuit substrates 71 cannot be protected bythe chassis base 60, and therefore, may be damaged by the externalimpact. In particular, as the size of the plasma display panel 30increases, the size of the chassis base 60, which is proportional to thesize of the plasma display panel 30, also increases, and therefore,becomes more susceptible to bending or twisting. Therefore, anadditional reinforcing structure 61 or reinforcing member 65 forprotecting the plasma display panel 30 is required.

Also, in that situation, the thickness of the chassis base 60, generallyformed of aluminum, must be increased to ensure a predeterminedstrength. However, the increased thickness is undesirable for making aslim display module. Furthermore, the chassis base 60, formed of analuminum material having a specific gravity of approximately 2.7,increases the total weight of the display module. Overall, the chassisbase 60, formed of an aluminum material, is a limiting factor in makinga lightweight and slim plasma display module.

FIG. 2 is an exploded perspective view of a plasma display moduleaccording to an embodiment of the present invention.

Referring to FIG. 2, the plasma display module includes a plasma displaypanel 130 forming a front portion of the plasma display module, achassis base 160 disposed behind the plasma display panel 130, and agrounding member 141 interposed between the plasma display panel 130 andthe chassis base 160. The plasma display panel 130 includes a firstpanel 110 and a second panel 120, and is an image display unit whereimages are displayed using a discharge effect.

The plasma display panel 130 and circuit substrates 171 in front of andbehind the chassis base 160, respectively, are supported by the chassisbase 160. In the present invention, the chassis base 160 may be formedof a non-metallic material or a plastic material, for example, athermoplastic resin material such as polypropylene, polyamide, etc. orthermosetting resin material such as phenol, epoxy, etc. Also, thechassis base 160 may be formed of a material comprising at least twodifferent resins, or a material comprising a resin as a main componentand an additive as a functional material to obtain some desiredproperties such as moldability, strength, or heat-resistance. Thechassis base 160 formed of a plastic material can be formed using aninjection molding method.

It is known that plastic materials are relatively inexpensive,lightweight and have high strength and good moldability, and therefore,there are various advantages to forming the chassis base 160 from aplastic material, such as productivity of the plasma display modules canbe increased, slim and lightweight plasma display modules can beproduced, and the plasma display modules can be protected from externalimpacts since the resistance to bending and twisting is high.

FIG. 3 is a perspective view of the chassis base 160 of FIG. 2 accordingto an embodiment of the present invention. Referring to FIG. 3, recesses161 having an approximately rectangular shape corresponding to a shapeof the circuit substrates 171 and coupling bosses 165 are formed asintegral parts of the chassis base 160 wherein the coupling bosses 165protrude a predetermined distance from a rear surface of the chassisbase 160 near each corner of the recesses 161.

The material of chassis base 160 framing each of the recesses 161 formribs 162 which add to the overall strength and rigidity of the chassisbase, and chassis base 160 is made lighter due to the formation of therecesses 161.

The coupling bosses 165 are used to mount the circuit substrates 171(see in FIG. 2). Screw members 180 (see in FIG. 2) used to fix thecircuit substrates 171 on the rear surface of the chassis base 160 arecoupled to the coupling bosses 165.

Referring again to FIG. 2, the circuit substrates 171 mounted on therear surface of the chassis base 160 generate a variety of differentdriving signals. To do this, a ground voltage as a uniform base voltagemust be applied to the circuit substrates 171. The grounding structureof the circuit substrates 171 will be described later. The drivingsignals generated by the circuit substrates 171 are applied to theplasma display panel 130 through connection cables 173 which extend fromthe circuit substrates 171.

A grounding member 141 is interposed between the plasma display panel130 and the chassis base 160. The grounding member 141 has a wide areain order to supply a uniform ground voltage to the circuit substrates171 that drive the plasma display panel 130.

In the current embodiment of the present invention, the grounding member141 for grounding the circuit substrates 171 is provided because thechassis base 160 is formed of a plastic insulating material in thepresent invention. The grounding member 141 may be formed of a metalhaving high electrical conductivity, for example, a thin aluminum filmor a thin copper film. The screw members 180 used to fix the circuitsubstrates 171 to the chassis base 160 are electrically connected to thegrounding member 141 through the chassis base 160. Therefore, thecircuit substrates 171 are grounded through the screw members 180 thatelectrically connect the grounding region of the circuit substrates 171to the grounding member 141. Here, the screw members 180 fix each cornerof the circuit substrates 171 to the chassis base 160. In this state,all screw members 180 that fix the circuit substrates 171 on the chassisbase 160 may be electrically connected to the grounding member 141, or,only some of the screw members 180 may be used for grounding the circuitsubstrates 171 and the rest of the screw members 180 may be used onlyfor fixing the circuit substrates 171 on the chassis base 160. Ofcourse, the screw members 180 that are used for grounding the circuitsubstrates 171 may also be used for fixing the circuit substrates 171 tothe chassis base 160.

Since the plasma display panel 130 displays images using a dischargeeffect, a large amount of heat is generated during the operation of theplasma display panel 130. If the heat is not rapidly dissipated, variouselectronic devices mounted on the plasma display panel 130 or thecircuit substrates 171 may be degraded, thereby adversely affectingoperation of the plasma display module. Accordingly, a heat dissipationmember having high thermal conductivity may be attached to the plasmadisplay panel 130. When the grounding member 141 according to thepresent invention is formed of a metal, the grounding member 141 canalso function as the heat dissipation member. For example, sincealuminum, which has thermal conductivity of 140 W/mk, dissipates heatvery well, the grounding member 141 formed of aluminum can rapidlydiffuse heat generated from the plasma display panel 130 in a planedirection.

Although it is not a required element in the present invention, aflexible thermal conductive member 143 may be interposed between thegrounding member 141 and the chassis base 160. The flexible thermalconductive member 143 may be formed of a flexible material having acertain degree of thermal conductivity, for example, silicon sheet. Theflexible thermal conductive member 143 is tightly interposed between thegrounding member 141 and the chassis base 160 to transmit heat therebetween. That is, an air layer in the flexible thermal conductive member143 can be compressed when the plasma display panel 130 and the chassisbase 160 are tightly coupled, and thus, the air of a heat dissipationpath can be removed from the plasma display module to the outside.

The flexible thermal conductive member 143 has a damping capability asit is formed of a flexible material, and therefore, can absorb avibration or an external impact. Therefore, the flexible thermalconductive member 143 can function to protect the plasma display panel130, formed of glass, from vibration generated during transportation ormoving of the plasma display module by absorbing the vibration. Inaddition the flexible thermal conductive member 143 can prevent anyvibration and noise generated by the plasma display panel 130 beingtransmitted outside of the plasma display module.

Also, if the flexible thermal conductive member 143 is formed of amaterial having adhesiveness, the flexible thermal conductive member 143can intermediate a mechanical coupling between the grounding member 141and the chassis base 160. Generally, the flexible thermal conductivemember 143 has a lower thermal conductivity than the grounding member141, for example, silicon sheet used to form the flexible thermalconductive member 143 has a thermal conductivity of approximately 1 to 5W/mk. Accordingly, it is of benefit to the heat dissipation of theplasma display panel 130 that the thickness of the flexible thermalconductive member 143 is limited according to the required flexibility.

The flexible thermal conductive member 143, formed of an electricalinsulator, may not be disposed in front of the screw members 180 so thatthe flexible thermal conductive member 143 does not block an electricalgrounding path P between the screw members 180 and the grounding member141. Referring to an example depicted in FIG. 2, the flexible thermalconductive member 143 and a flexible connection member 145, which itselfforms a portion of the grounding path P and will be described later, maybe interposed in different areas between the grounding member 141 andthe chassis base 160 as to not overlap each other.

The flexible connection member 145 together with the flexible thermalconductive member 143 can be interposed between the grounding member 141and the chassis base 160. In the example depicted in FIG. 2, the twoflexible connection members 145 are disposed on upper and lowerextremities of the flexible thermal conductive member 143. Although itis not a required element in the present invention, the provision of theflexible connection member 145 is of benefit to grounding safety. Theflexible connection member 145 is tightly sandwiched between thegrounding member 141 and the chassis base 160 to form a grounding path Ptherebetween. For this purpose, the flexible connection member 145 isformed to have flexibility or buffering capability together withelectrical conductivity.

FIG. 4 is a perspective view of the flexible connection member 145 ofFIG. 2, according to an embodiment of the present invention. As depictedin FIG. 4 the flexible connection member 145 can be formed of aconductive sponge. The conductive sponge depicted in FIG. 4 includes asponge 146 that allows flexibility and a metal mesh 147 that surroundsthe exterior of the sponge 46 and provides electrical conductivity.

As shown in FIG. 2, strips of double-sided tape 150 are attached alongouter areas of the grounding member 141 between the plasma display panel130 and the chassis base 160. The plasma display module is assembled byapplying a pressure between the plasma display panel 130 and the chassisbase 160 when the strips of double-sided tape 150 are interposed therebetween.

FIG. 5 is a partial cross-sectional view of the plasma display moduletaken along line V-V of FIG. 2, according to an embodiment of thepresent invention.

Referring to FIG. 5, the grounding member 141 and the flexibleconnection member 145 that contacts the grounding member 141 areinterposed between the plasma display panel 130 and the chassis base160. Coupling bosses 165 are formed as an integral part of the chassisbase 160 on a rear surface of the chassis base 160. Each circuitsubstrate 171 is fixed on the rear of the chassis base 160 by couplingthe screw members 180 to the coupling bosses 165 through the circuitsubstrate 171. Each coupling boss 165 has a screw hole in which aninternal screw thread is formed, and the screw member 180 coupled to thecoupling boss 165 may protrude a predetermined depth d from the side ofthe chassis base 160. As a result, the screw member 180 can contact theflexible connection member 145 with a predetermined pressure. Theflexible connection member 145 pressed by the screw member 180 tightlycontacts the grounding member 141, and intermediates an electricalconnection between the screw member 180 and the grounding member 141.

Since the flexible connection member 145 is tightly interposed betweenthe screw member 180 and the grounding member 141, a connection failurebetween the screw member 180 and the grounding member 141 does not occurdespite any assembling or manufacturing errors and a predeterminedmargin of error for stable connection can be ensured. The flexibleconnection member 145 completes a grounding path P of the circuitsubstrate 171 by electrically connecting the screw member 180 to thegrounding member 141, and thus, the circuit substrate 171 is grounded tothe grounding member 141 through the screw member 180 and the flexibleconnection member 145.

In the plasma display module according to the present invention, aplastic material which is inexpensive and lightweight, and has highstrength and good moldability is used to form the chassis base.Therefore, productivity of the plasma display modules can be increased,slim and lightweight plasma display modules can be produced, and theplasma display modules can be protected from external impacts sinceresistance to bending and twisting is high.

In particular, in the present invention, since the chassis base isformed of an insulating material, a metal thin film grounding member isprovided to serve as a grounding member instead of the chassis base asin the prior art, and a new grounding structure in which the circuitsubstrate and the grounding member are electrically connected isprovided.

While the present invention has been particularly shown and describedwith reference to exemplary embodiments thereof, it will be understoodby those of ordinary skill in the art that various changes in form anddetails may be made therein without departing from the spirit and scopeof the present invention as defined by the following claims.

1. A plasma display module comprising: a chassis base formed of anon-metallic material; a plasma display panel disposed in front of thechassis base to display images; a plurality of circuit substratesdisposed on a rear surface of the chassis base to drive the plasmadisplay panel; a grounding member disposed between the chassis base andthe plasma display panel, the grounding member being formed of aconductive material so that the grounding member can provide a groundvoltage to the circuit substrates when the circuit substrates aregrounded to the grounding member; and a plurality of screw membersfixing the circuit substrates to the chassis base, at least one of saidscrew members grounding circuit substrates to the grounding member byelectrically connecting the circuit substrates to the grounding memberthrough the chassis base.
 2. The plasma display module of claim 1,further comprising: a flexible connection member having a bufferingcapability together with electrical conductivity, said flexibleconnection member being interposed between the chassis base and thegrounding member, said flexible connection member forming an electricalconnection between said at least one screw member and the groundingmember.
 3. The plasma display module of claim 2, wherein said at leastone screw member protrudes a predetermined distance from the chassisbase so that the screw member can elastically press the flexibleconnection member against said grounding member.
 4. The plasma displaymodule of claim 2, wherein the flexible connection member is formed of asponge and a metal mesh that surrounds the sponge.
 5. The plasma displaymodule of claim 2, wherein the flexible connection member is formed of asponge and a metal mesh that surrounds the sponge.
 6. The plasma displaymodule of claim 1, further comprising: a flexible thermal conductivemember having a buffering capability together with thermal conductivity,said flexible thermal conductive member being tightly sandwiched betweenthe chassis base and the grounding member so that the flexible thermalconductive member can intermediate heat transfer from the chassis baseto the grounding member.
 7. The plasma display module of claim 6,wherein the flexible thermal conductive member is formed of siliconsheet.
 8. The plasma display module of claim 1, wherein the groundingmember has a high degree of thermal conductivity for rapidly diffusingheat generated from the plasma display panel.
 9. The plasma displaymodule of claim 8, wherein the grounding member is formed of aluminum.10. The plasma display module of claim 1, further comprising: a flexibleconnection member that intermediates electrical connection by beingtightly sandwiched between the grounding member and one of the screwmembers that has passed through the chassis base; and a flexible thermalconductive member that intermediates heat transfer by being tightlysandwiched between the grounding member and the chassis base, saidflexible connection member and said flexible thermal conductive membereach being interposed in different areas between the grounding memberand the chassis base.
 11. The plasma display module of claim 1, whereinthe chassis base comprises: a plurality of recesses formed in a rearsurface area of the chassis base for receiving said plurality of circuitsubstrates; and a plurality of coupling bosses for receiving saidplurality of screw members, said coupling bosses being formed as anintegral part of the chassis base protruding from said recesses.
 12. Theplasma display module of claim 11, wherein the chassis base furthercomprises: a plurality of ribs framing said plurality of recesses, saidribs providing added strength and rigidity to said chassis base.
 13. Theplasma display module of claim 1, wherein the non-metallic materialforming the chassis base is comprised of a plastic material.
 14. Theplasma display module of claim 1, wherein the non-metallic materialforming the chassis base is comprised of a thermoplastic resin materialor a thermosetting resin material.
 15. A plasma display modulecomprising: a plasma display panel; a chassis base formed of anon-metallic material, said chassis base being fastened to said plasmadisplay panel by double sided tape disposed adjacent outer edges of saidplasma display panel; a plurality of circuit substrates disposed on arear surface of the chassis base to drive the plasma display panel; agrounding member disposed between said plasma display panel and saidchassis base, said grounding member being formed of a conductivematerial; and a plurality of screw members fixing said plurality ofcircuit substrates to the chassis base, at least one of said screwmembers grounding said circuit substrates to the grounding member byelectrically connecting the circuit substrates to the grounding memberthrough the chassis base.
 16. The plasma display module of claim 15,wherein the non-metallic material forming the chassis base is comprisedof a plastic material.
 17. The plasma display module of claim 15,wherein the non-metallic material forming the chassis base is comprisedof a thermoplastic resin material or a thermosetting resin material. 18.The plasma display module of claim 15, wherein the chassis basecomprises: a plurality of recesses formed in a rear surface area of thechassis base for receiving said plurality of circuit substrates; and aplurality of coupling bosses for receiving said plurality of screwmembers, said coupling bosses being formed as an integral part of thechassis base protruding from said recesses.
 19. The plasma displaymodule of claim 18, wherein the chassis base further comprises: aplurality of ribs framing said plurality of recesses, said ribsproviding added strength and rigidity to said chassis base.
 20. Theplasma display module of claim 15, further comprising: flexibleconnection members having a buffering capability together withelectrical conductivity, said flexible connection members being tightlysandwiched between the chassis base and the grounding member, at leastone of said flexible connection members forming an electrical connectionbetween said at least one screw member and the grounding member; and aflexible thermal conductive member disposed between said flexibleconnection members, said flexible thermal conductive member having abuffering capability together with thermal conductivity, said flexiblethermal conductive member being tightly sandwiched between the chassisbase and the grounding member so that the flexible thermal conductivemember can intermediate heat transfer from the chassis base to thegrounding member.